JP2000078232A - Method for operating portable communication equipment and method for managing operation of the portable communication equipment - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide the operating method for a portable communication equipment, where a data loss caused by the portable communication equipment when the device is moved between different communication configurations. SOLUTION: This method validates changes in the operation of portable communication equipment 101 such as a laptop computer, palmtop computer, a personal data assistant(PDA), or a cellular telephone set. This equipment 101 uses either of two different communication configurations 170, 171 or more for making communication with a remote host, that is, a server 151. Various signals, denoting an environment where the device is in operation, are monitored by predicting or estimating the change or the transition from one communication configuration to another communication configuration. When the changes are important, the operation change is validated at the same time by changing the parameters of a transport protocol layer and the application protocol layer in the equipment.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method of operating a portable communication device such as a laptop computer, a palmtop computer, a personal digital assistant (PDA) or a cellular telephone, and more particularly to the use of the device. In accordance with a predicted or anticipated change in communication configuration (i.e., a change in a network protocol parameter or a link level protocol parameter), a change in a parameter at a transport protocol layer and / or an application protocol layer in the device causes the operation of the device to be performed. How to enable change.

[0002]

2. Description of the Related Art Modern portable communication devices, such as laptop computers, palmtop computers, personal digital assistants (PDAs) or cellular telephones, use two or more different communication configurations, depending on various external factors. And can work. For example, a hand-held digital terminal can use a wireless local area network (e.g., WaveLAN (Lucent TeX) when the device is indoors.
(registered trademark of Chnologies)) allows data to be sent to and received from a remote server or host.

[0003] Thereafter, when the device moves outdoors, the device may be configured to communicate over a cellular (eg, GSM) network. In the example described above, when the device moves outdoors, it may move from a wide bandwidth environment to a narrow bandwidth environment, and various other communication characteristics (eg,
Bit error rate, delay, jitter, loss, etc.) can also change. These changes are typically evident in the processor that controls the operation of the device by network or link level protocol signals.

In portable devices according to the prior art,
When sudden changes or discontinuities, such as a decrease in bandwidth, occur in the communication configuration, the performance of the device decreases, for example,
The image becomes ambiguous or the received signal becomes noisy or distorted. In some existing configurations, this degradation is detected and allowed by intentionally reducing the accuracy of the received and / or transmitted signals, or by reducing the resolution of the display, or by reducing the image quality. Steps have been taken to correct the problem, such as by reducing the size of.

[0005] Such an approach is reactive in that a change in the communication configuration occurs first, and in response to detecting the fact that performance has degraded, a change in the operation of the portable device then occurs. In a reactive approach, data can be lost because the change itself can take a considerable amount of time, during which time device operation is not optimal and the quality of service perceived by the user is reduced. Become.

One example of the aforementioned reactive approach is RW
Chen, P. Krzyzanowski, M. Lyu, C. Sreenan and
"Renegotiable Quality of Service-A New" announced 27 times by J. Trotter (all belonging to Lucent Technologies) at PTCS, June 1997, Seattle, WA.
Scheme for Fault Tolerance in Wireless Networks "
It is shown in a paper entitled:

This document relates to a device wherein a link layer protocol is configured to determine that the available bandwidth for the device has changed. The link layer protocol can signal this change to a layer above the protocol stack, including the application layer protocol, for example, in response to which application can change its data rate.

[0008] Other reactive approaches are in modems, in Internet applications, and in MPEs.
It has been used in images processed by the G standard. In relation to a given "intelligent" modem, the bit rate at which the modem operates can be changed reactively, for example, in response to channel conditions inferred from error rate or placement scatter measurements. In the context of the Internet, it is generally known that the TCP / IP protocol stack can be configured to adapt in time to the fact that the available bandwidth available to Internet equipment has changed. .

[0009] This adaptation is intended to allow the application to change its rate, or at least to ensure that the application's data is buffered, so that the data is not lost in the network due to improper bandwidth. Can be used. With respect to image processing, the MPEG standard defines an application protocol layer that can be configured in such a way that it can provide output at different bit rates based on being informed of what bandwidth is available. Consider.

[0010]

In each of the above-described reactive approaches, a change is first observed in the communication configuration used by the device. Then, changes to the operation of the device itself are caused by changes in the application layer protocol. This reaction process is
Takes time, during which time data may be lost and / or performance may be impaired. Therefore, the challenge in the prior art is to provide a speedy change to minimize or eliminate data loss, or at least to provide a change that is as harmless as possible if some data loss is encountered during the change. Is not possible.

[0011]

According to the present invention, a portable communication device includes a remote host or server and a remote host.
Communication may be performed using one of more than one different communication configurations. Changes in the communication configuration used by the portable communication device are predicted or anticipated by monitoring various signal indicators of the environment in which the device is operating. If the change is determined to be imminent and significant, the operation of the portable device is changed, typically by adjusting parameters in an application layer protocol or a transport layer protocol. Therefore, the change in the operation of the device occurs virtually simultaneously with the change in the communication configuration.

In one embodiment of the present invention, a signal or flag is generated in response to a significant change in signal strength that has occurred in a communication configuration in which the device can be used. And
The flag explicitly signals the change to one or more application protocol layers and / or communication transport protocol layers running on the device. Where the characteristics of one or more applications change, the application protocol layer is involved.

[0013] For example, this change is caused by an image displayed on a display screen that is part of the device.
For example, by changing the window size, resolution, frame rate, or other characteristics of the image,
May affect properties. Where the transport protocol layer is involved, changes can affect the size of the packets by which the information is carried, or the properties by which the information is buffered or stored. In any case, according to the present invention, if there is a change in the communication configuration used by the device, the operation of the device itself will change almost simultaneously.

As an example, in a laptop computer communicating with a remote host via a wireless communication link, if the laptop is moving from one location to another, a first communication configuration (eg, indoor use) In a WaveLAN® communication configuration, a decrease in signal strength is detected, and at the same time, in a second communication configuration (eg, a GSM network used outdoors)
An increase in signal strength is detected.

[0015] This indicates that there is a great potential for imminent changes in the communication channel between the laptop and the remote host or server. The present invention provides for a display driver operating on a laptop computer, as this change can lead to a change corresponding to a narrow bandwidth transmission channel (eg, 10 kbps) from a wide bandwidth (eg, 10 Mbps). By changing the data rate almost simultaneously, the display resolution is reduced to accommodate the reduced bandwidth without data loss.

In another embodiment of the present invention, changes in the communication configuration are predicted in the near future based on observing operational changes in other communication characteristics, such as jitter, noise, distortion, and the like. Or can be expected. If it is determined that a significant change in one or more of these characteristics occurs within a predetermined time, it is warned in advance that the application protocol layer will begin to be suppressed even before the change in communication configuration actually occurs. Is done. If the portable device is configured to allow access to geographic location information via a global positioning (GPS) system, the information may be an additional indication that the communication configuration will change soon or the length of time mentioned above. It can be used as an indirect factor in determining soundness.

[0017]

FIG. 1 shows a general configuration of a portable communication device 101 that can use the present invention.
The case where communication with the remote server 151 is performed is shown. According to the invention, the device 101 comprises a laptop computer, a palmtop computer, a 3Com
It could be a personal digital assistant (PDA) such as the Palm Pilot III sold by the company, a cellular telephone with a graphical display such as the GENIE available from Phillips Communications or other similar devices.

For purposes of understanding the present invention, portable device 101 includes a processor 110 that controls the overall operation of the device. As is well known, processor 1
10 includes hardware and software elements that control the functions of the device. Mechanistically and functionally, the processor 110 may include a multi-layer protocol stack 140 according to the Open Systems Interconnection (OSI) defined by the ISO.

Layers in the protocol stack include a link layer 144 that manages data transmission over the added communication link, and a network layer 14 that provides a means for end-to-end transmission of data packets.
3. There is a transport layer 142 that manages the sending of application messages and an application layer 141 that interfaces with and manages user-level programs.

The device 101 can include a display 120 configured to display image information. Thus, if device 101 is a laptop or palmtop computer, display 120 may be an active matrix display panel. If device 101 is a cellular telephone, display 120 can be an LCD display screen.

The device 101 is configured to communicate with a remote location, such as a server 151, via at least two different communication interfaces 130 and 131. However, at any one time, only one communication configuration is being used. The first communication interface 130 is provided between the device 101 and the GSM base station 17.
GSM interface that allows communication between the GSM and the GSM.

A signal generated in the device 101 is transmitted from the base station 170 to the remote server 151 via the Internet 175. The second communication interface 131 is connected to the device 101 and WaveLAN (registered trademark).
WaveLAN enabling communication with base station 171
(Registered trademark) interface. Base station 17
From 1, a signal generated in the device 101 is communicated to the remote server 151 via the Internet 175.

According to the present invention, the communication interface 13
0 and 131 provide to processor 110 information indicating the strength of the communication signal received at the interface from the remote base station or other device with which device 101 communicates.
This capability can be obtained using power measurement or other signal strength measurement techniques well known to those skilled in the art.

The server 151 stores the protocol stack 14
Processor 160 including a multilayer protocol stack 190 that is substantially similar to and compatible with
Is controlled by The protocol stack 190 includes a link layer 194, a network layer 193, a transport layer 192, and an application layer 191.

Depending on the communication configuration used by the device 101, the server 151 may use the first communication interface 180 or WaveLA to handle GSM traffic.
It communicates with the device 101 (similarly, other devices) via any of the second communication interfaces 181 that handle N (trademark) traffic. The server 151 also communicates with many other devices not shown.

Portable device 101 and server 151
Are not shown because those skilled in the art will recognize that the details are not necessary to practice the invention. However, the logic and processes described below are based on properly programmed general purpose hardware,
It can be implemented in special purpose hardware such as an ASIC, and in various other ways.

FIG. 2 shows that the portable communication device of FIG.
To change from one communication configuration to a different communication configuration,
Show how it can work. The user 201
At a location 210, a portable laptop device 101 is being carried. Since the user 201 is indoors, a signal from the device 101 and a signal to the device 101 are transmitted to the WaveLAN base station, that is, the concentrator 21.
1 is transmitted and received via a wireless link, and the concentrator 211 is connected to the Internet 175.

However, the user 201 may move toward the door and at the exit to the outdoors,
Communication changes to a second communication configuration, ie, from using a wireless link to a GSM base station 221, G
The SM base station 221 is configured to communicate with the Internet 175. At any one time, only one of the communication configurations is in use, but the device 101
Can simultaneously receive signals from both communication configurations. As explained below, these signal changes can be evaluated and the second
Is one approach that is useful in determining whether there is a potential change to the communication configuration.

Referring to FIG. 3, a flow chart illustrating the process according to the present invention is shown, in which a determination is made as to whether a change in the communication configuration used by the apparatus of FIG. In this process, which may occur at the network layer 143 of the processor 110,
The device 101 has a first communication configuration (for example, WaveLA
N networks) or a second communication configuration (eg, GS
(M network) can be used to communicate with the server 151.

At any one time, only one communication configuration may be used by device 101 to communicate with server 151, but device 101 nevertheless, according to the present invention, nevertheless, both communication configurations That is, it is configured to be able to determine a predetermined attribute of a communication configuration currently used and a communication configuration that may be used at a future time when the device 101 moves, for example.

These attributes may include signal strength, noise level, jitter, distortion or other similar factors related to link protocol level 144 and network protocol level 143. The bandwidth characteristics of these configurations are that the WaveLAN network is approximately 10 Mbps.
GSM networks have a much higher bandwidth (100
It is very different because it has a narrow bandwidth of about 10 kbps.

After the process of FIG. 3 starts at step 301, at step 303 the values of certain attributes of different communication configurations that can be used by the portable device 101 are determined. As an example, using the attribute of the signal strength S at the time t, the signal strength S (A ₁ , t) measured in the device using the _first communication configuration (A ₁ ) and the second communication configuration (A ₂₎ The determination of the measured signal strength S (A ₂ , t) in the instrument using ()) is made in this step.

Next, in step 305, the value of the signal strength is determined again at a short time t + Δ. δ
t is a very short time of, for example, 50 ms. These values are S (A ₁ , t + δt) and S (A ₂ ,
t + δt). In step 307, extrapolation is performed based on the information gathered in steps 303 and 305. Specifically, the time δt
, The rate of change of the signal strength using each of the communication configurations is determined, and this derivative is determined at a future time t + Δ
The signal strength values S (A ₁ , t + ΔT) and T at T
Used to determine (A ₂ , t + ΔT). Here, ΔT> δt. When performing extrapolation, linearity may be assumed as a first order approximation.

In step 309, the signal strength value S
(A ₁ , t + ΔT) and S (A ₂ , t + ΔT) are compared with respective thresholds T ₁ and T ₂ . The first communication configuration is the one currently used by the device 101,
Second communication configuration, represented Assuming those used in the future, a signal strength level that operation becomes difficult equipment under than the threshold value T ₁ is. Similarly, T ₂
Represents a signal strength level above which the operation of the device is usually not difficult. Once S (A ₁ , t + ΔT) <T ₁ and S (A ₂ , t + ΔT)> T ₂ have been determined in step 309, in step 311, a signal indicating that the process of FIG. Generated.

The device 101 of FIG. 1 includes a global positioning (GPS) receiver 112 configured to provide output information to the processor 110 indicating the current geographic location of the device 101.
Can be optionally included. This information can be used in various ways in the context of the present invention. First,
The GPS information may be used in step 307 to select a value for ΔT. Specifically, when the device 101 is moving fast, ΔT must be relatively small compared to a value when the device is moving slowly.
Second, this GPS information may be used in step 309, in conjunction with other information related to the different available communication configuration boundary topologies, to better predict the occurrence of communication configuration changes. .

Signal strength is the attribute measured in the above example, but other attributes could be used. These include, for example, jitter, noise, distortion, and the like.

FIG. 4 shows a flow chart of the process according to the invention, by means of which the application protocol layer or the transport protocol layer in the device indicates that there is a predicted change in the communication configuration in FIG. Notified when process is determined. This may include, at substantially the same time that the device moves from the first communication configuration to the second communication configuration, the appropriate one or more transport protocol or application protocol parameters controlling the operation of the device. It is done so that changes can be made.

After the process of FIG. 4 is started in step 401, in step 403, the device 101
A determination is made as to whether a change in the communication configuration has been predicted, ie, whether a signal has been generated in step 311 of FIG. If there is no change, the process of FIG. 4 returns to step 401 and repeats after an appropriate delay. If the result in step 403 is positive (yes)
If it is, at step 405, first application A ₁ currently running in the device 101 is selected.

For example, if the device 101 is a laptop computer, the application may include an Internet web browser, MPEG, audio / video player or file transfer application, or the like. For the selected application,
The process continues at step 407, where the utility function U (A ₁ ) for the application
Is evaluated and, if the application is used in the first communication configuration, the value of U ₁ (A ₁ ) indicating the overall effectiveness indicator or the value of the application is determined by the application in the second communication configuration. When used, it is compared to U ₂ (A ₁ ), which represents the overall effectiveness indicator or value of the application.

This comparison can calculate the difference between U ₁ (A ₁ ) and U ₂ (A ₁ ) and compare the absolute value of the difference to a threshold T ₁ applicable to a particular application. be able to. This absolute value | U ₂ (A ₁ ) −U ₁ (A ₁ )
If |> T ₁ is determined, this indicates that the validity of the selected application changes significantly when the device moves from the first communication environment to the second communication environment.

In this case, a positive (yes) result is obtained in step 407 and the process proceeds to step 409
And a signal is generated and provided to either the transport layer 142 or the application layer 141 to modify the operation of the device. FIG.
And since the operation of the process of FIG. 4 can be completed before the device 101 is actually moved from the first communication environment to the second communication environment, there is sufficient time for the modification to take effect, which is advantageous. In particular, it occurs virtually simultaneously with a change in the communication configuration.

In step 409, a signal is generated,
When given to the application layer in device 101, various operational changes may be made depending on the particular application involved. For example, if the application is a video player configured according to the MPEG standard, the resolution of the player may be adjusted or the frame rate at which images are processed may be changed.

In some situations, step 409
At, additional control signals may be sent from the processor 110 in the portable device 101 to the remote server 151 to effect a change in operation of a corresponding application running on the processor 160. In this example, the server may be notified of the change in resolution in the portable device 101 and / or may cause the server to treat the application differently.

In step 409, a signal is generated,
When given to the transport layer in device 101, other changes may be made depending on the particular application involved. For example, if the TCP protocol is used in connection with Internet communication, the TCP "sending window size" or "receiving window size" may be adjusted.

The utility functions described above include bandwidth,
It is useful to evaluate a number of factors that affect the effective operation of a portable device of the type used in connection with the present invention, such as delay, jitter, loss and cost. For example, a laptop computer running an Internet browser application is a wireless Wave
Consider communicating with a remote host via a LAN (first communication configuration) or a wireless GSM system (second communication configuration).

When the bandwidth of the GSM communication configuration is WaveLAN
It is convenient for browser applications to download and display only text without images if it is much narrower than using. On the other hand, if the laptop is running a facsimile application, such a change in bandwidth may not be significant, as long as the fax information is finally passed, the fax application can operate effectively in the background. Absent.

As another example, a user of a cellular telephone may
Consider the case where you are in an area where service can be obtained from two different cellular service providers. Cellular telephones provide a primary
From one cellular network to a second cellular network. Assume that the connection costs using two different communication configurations are different and depend on the amount of data transmitted rather than talk time. By comparing the utility function (cost in this example) for each communication configuration, the codec in the cellular telephone adjusts to operate with lower accuracy, reducing the amount of data transmitted and consequently the call May be determined to be preferable.

The validity of the selected application is
If it is determined that there is no significant change in the second communication environment compared to the first communication environment, that is, | U ₂ (A ₁ ) −U
₁ (A ₁ ) | <T ₁ , negative result (no)
Are obtained in step 407. In this case, at step 411, a determination is made as to whether additional applications running on device 101 require evaluation. If an evaluation is required, the process continues by repeating step 405 for the next application. If no evaluation is required, the result of step 411 is "No" and the process returns to step 401.

[0049]

As described above, according to the present invention,
An operation method of a portable communication device capable of minimizing data loss when moving between different communication configurations can be provided.

[Brief description of the drawings]

FIG. 1 is a block diagram illustrating a general configuration of a portable communication device capable of communicating with a remote host or server using one of two or more different communication configurations.

FIG. 2 is a diagram illustrating how the portable communication device of FIG. 1 can operate such that a transition from one communication configuration to a different communication configuration occurs.

FIG. 3 is a flowchart illustrating a process according to the present invention, illustrating determining that a change in the communication configuration used by the apparatus of FIG. 1 will occur shortly.

FIG. 4 is a flowchart showing a process according to the present invention, which shows that an application or a transport protocol layer in a device is notified when the process of FIG. 3 predicts a change in communication configuration. This is done to make appropriate changes in one or more transport or application protocol parameters that control the operation of the device.

[Explanation of symbols]

 101 Portable Device 102 Display 110, 160 Processor 130 Communication Interface 140, 190 Multilayer Protocol Stack 141, 191 Application 142, 192 Transport 143, 193 Network 144, 194 Link 151 Server 170 GSM Base Station 171 WaveLAN Base Station 175 Internet 180 GSM Communication interface 181 WaveLAN communication interface

 ──────────────────────────────────────────────────続 き Continuation of the front page (71) Applicant 596077259 600 Mountain Avenue, Murray Hill, New Jersey 07974-0636 U.S.A. S. A. (72) Inventor Richard Dennis Gitlin United States, 07739 New Jersey, Little Silver, Windsor Live 42 (72) Inventor Ramachandran Ramsey United States, 07747 New Jersey, Matawan, Rabin Drive, Tree Haven 1, Apartment 14A (72) Inventor Thomas Yat Chung Woo United States, 07701 New Jersey, Red Bank, Kimberley Court 13, Apartment 75

Claims (10)

[Claims] 1. A method of operating a portable communication device capable of communicating with a remote server via at least first and second different communication configurations, wherein the method is used by the portable communication device to communicate with the remote server. Monitoring at least one signal indicative of the environment in which the device is operating to predict a change in communication configuration; and using the device if the monitoring step determines that a significant change has been detected. Adjusting the operation of the portable device by adjusting at least one parameter affecting a signal included in the application layer protocol or the transport layer protocol. 2. The method of claim 1, wherein the portable communication device is a communication device selected from the group consisting of a laptop or palmtop computer, a personal digital assistant (PDA), and a cellular telephone. . 3. The portable communication device includes a software controlled processor and at least first and second communication interfaces respectively associated with the at least first and second different communication configurations, wherein the monitoring step comprises: 3. The method of claim 2, wherein the method is performed at a network protocol layer of the processor using signals received from the first and second communication interfaces. 4. A multi-layer protocol stack including at least one application protocol layer for controlling user-level operation of a portable communication device and a communication protocol layer for controlling transmission of data to the device and reception of data by the device. Determining the likelihood that a change in the rate at which the portable communication device will transmit or receive data to a remote location will occur, the method comprising managing the operation of a portable communication device having a processor controlled by the instructions. Responsive to the determining step and substantially simultaneously with the occurrence of a change in the rate at which the portable communication device transmits or receives data to a remote location,
Changing the operation of the portable communication device by changing at least one parameter that controls the application protocol layer. 5. The apparatus of claim 4, wherein the device includes a display for image information, and wherein the changing comprises changing a characteristic of an image displayed on the display. Method. 6. The method of claim 5, wherein the characteristics include a size or a resolution of the image. 7. The method of claim 6, wherein said determining comprises monitoring changes in operation of said communication protocol layer. 8. The apparatus, wherein the device comprises a GPS system, wherein the determining comprises monitoring a change in a geographical location of the device as a result of a signal generated by the GPS system. Claim 4
The described method. 9. The method of claim 8, wherein said changing comprises changing a parameter in said application protocol layer. 10. The method of claim 9, wherein the determining comprises monitoring the strength of a signal received by or transmitted from the device.
The described method.